md5(1) [freebsd man page]

MD5(1)							    BSD General Commands Manual 						    MD5(1)

NAME

     md5, sha1, sha256, sha512, rmd160 -- calculate a message-digest fingerprint (checksum) for a file

SYNOPSIS

     md5 [-pqrtx] [-c string] [-s string] [file ...]
     sha1 [-pqrtx] [-c string] [-s string] [file ...]
     sha256 [-pqrtx] [-c string] [-s string] [file ...]
     sha512 [-pqrtx] [-c string] [-s string] [file ...]
     rmd160 [-pqrtx] [-c string] [-s string] [file ...]

DESCRIPTION

     The md5, sha1, sha256, sha512 and rmd160 utilities take as input a message of arbitrary length and produce as output a ``fingerprint'' or
     ``message digest'' of the input.  It is conjectured that it is computationally infeasible to produce two messages having the same message
     digest, or to produce any message having a given prespecified target message digest.  The MD5, SHA-1, SHA-256, SHA-512 and RIPEMD-160 algo-
     rithms are intended for digital signature applications, where a large file must be ``compressed'' in a secure manner before being encrypted
     with a private (secret) key under a public-key cryptosystem such as RSA.

     MD5 has been completely broken as far as finding collisions is concerned, and should not be relied upon to produce unique outputs.  This also
     means that MD5 should not be used as part of a cryptographic signature scheme.  At the current time (2014-05-17) there is no publicly known
     method to ``reverse'' MD5, i.e., to find an input given a hash value.

     SHA-1 currently (2014-05-17) has no known collisions, but an attack has been found which is faster than a brute-force search, placing the
     security of SHA-1 in doubt.

     It is recommended that all new applications use SHA-256 instead of one of the other hash functions.

     The following options may be used in any combination and must precede any files named on the command line.  The hexadecimal checksum of each
     file listed on the command line is printed after the options are processed.

     -c string
	     Compare the digest of the file against this string.  (Note that this option is not yet useful if multiple files are specified.)

     -s string
	     Print a checksum of the given string.

     -p      Echo stdin to stdout and append the checksum to stdout.

     -q      Quiet mode -- only the checksum is printed out.  Overrides the -r option.

     -r      Reverses the format of the output.  This helps with visual diffs.	Does nothing when combined with the -ptx options.

     -t      Run a built-in time trial.

     -x      Run a built-in test script.

EXIT STATUS

     The md5, sha1, sha256, sha512 and rmd160 utilities exit 0 on success, 1 if at least one of the input files could not be read, and 2 if at
     least one file does not have the same hash as the -c option.

SEE ALSO

     cksum(1), md5(3), ripemd(3), sha(3), sha256(3), sha512(3)

     R. Rivest, The MD5 Message-Digest Algorithm, RFC1321.

     J. Burrows, The Secure Hash Standard, FIPS PUB 180-2.

     D. Eastlake and P. Jones, US Secure Hash Algorithm 1, RFC 3174.

     RIPEMD-160 is part of the ISO draft standard "ISO/IEC DIS 10118-3" on dedicated hash functions.

     Secure Hash Standard (SHS): http://csrc.nist.gov/cryptval/shs.html.

     The RIPEMD-160 page: http://www.esat.kuleuven.ac.be/~bosselae/ripemd160.html.

ACKNOWLEDGMENTS

     This program is placed in the public domain for free general use by RSA Data Security.

     Support for SHA-1 and RIPEMD-160 has been added by Oliver Eikemeier <eik@FreeBSD.org>.

BSD
								   May 17, 2014 							       BSD

CKSUM(1)						    BSD General Commands Manual 						  CKSUM(1)

NAME

     cksum, md2, md4, md5, rmd160, sha1, sum -- display file checksums and block counts

SYNOPSIS

     cksum [-n] [-a algorithm [-ptx] [-s string]] [-o 1|2] [file ... | -c [-w] [sumfile]]
     sum [-n] [-a algorithm [-ptx] [-s string]] [-o 1|2] [file ... | -c [-w] [sumfile]]
     md2 [-nptx] [-s string] [file ... | -c [-w] [sumfile]]
     md4 [-nptx] [-s string] [file ... | -c [-w] [sumfile]]
     md5 [-nptx] [-s string] [file ... | -c [-w] [sumfile]]
     rmd160 [-nptx] [-s string] [file ... | -c [-w] [sumfile]]
     sha1 [-nptx] [-s string] [file ... | -c [-w] [sumfile]]

DESCRIPTION

     The cksum utility writes to the standard output three whitespace separated fields for each input file.  These fields are a checksum CRC, the
     total number of octets in the file and the file name.  If no file name is specified, the standard input is used and no file name is written.

     The sum utility is identical to the cksum utility, except that it defaults to using historic algorithm 1, as described below.  It is provided
     for compatibility only.

     The md2, md4, md5, sha1, and rmd160 utilities compute cryptographic hash functions, and write to standard output the hexadecimal representa-
     tion of the hash of their input.

     The options are as follows:

     -a algorithm
	     When invoked as cksum, use the specified algorithm.  Valid algorithms are:

		   Algorithm	Bits	Description
		   CRC		32	Default CRC algorithm
		   MD2		128	MD2, per RFC1319
		   MD4		128	MD4, per RFC1320
		   MD5		128	MD5, per RFC1321
		   RMD160	160	RIPEMD-160
		   SHA1 	160	SHA-1, per FIPS PUB 180-1
		   SHA256	256	SHA-2
		   SHA384	384	SHA-2
		   SHA512	512	SHA-2
		   old1 	16	Algorithm 1, per -o 1
		   old2 	16	Algorithm 2, per -o 2

     -c [sumfile]
	     Verify (check) files against a list of checksums.	The list is read from sumfile, or from stdin if no filename is given.  E.g. first
	     run
		   md5 *.tgz > MD5
		   sha1 *.tgz > SHA1
	     to generate a list of MD5 checksums in MD5, then use the following command to verify them:
		   cat MD5 SHA1 | cksum -c
	     If an error is found during checksum verification, an error message is printed, and the program returns an error code of 1.

     -o      Use historic algorithms instead of the (superior) default one.

	     Algorithm 1 is the algorithm used by historic BSD systems as the sum(1) algorithm and by historic AT&T System V UNIX systems as the
	     sum(1) algorithm when using the -r option.  This is a 16-bit checksum, with a right rotation before each addition; overflow is dis-
	     carded.

	     Algorithm 2 is the algorithm used by historic AT&T System V UNIX systems as the default sum(1) algorithm.	This is a 32-bit checksum,
	     and is defined as follows:

		   s = sum of all bytes;
		   r = s % 2^16 + (s % 2^32) / 2^16;
		   cksum = (r % 2^16) + r / 2^16;

	     Both algorithm 1 and 2 write to the standard output the same fields as the default algorithm except that the size of the file in
	     bytes is replaced with the size of the file in blocks.  For historic reasons, the block size is 1024 for algorithm 1 and 512 for
	     algorithm 2.  Partial blocks are rounded up.

     -w      Print warnings about malformed checksum files when verifying checksums with -c.

     The following options apply only when using the one of the message digest algorithms:

     -n      Print the hash and the filename in the normal sum output form, with the hash at the left and the filename following on the right.

     -p      Echo input from standard input to standard output, and append the selected message digest.

     -s string
	     Print the hash of the given string string.

     -t      Run a built-in message digest time trial.

     -x      Run a built-in message digest test script.  The tests that are run are supposed to encompass all the various tests in the suites that
	     accompany the algorithms' descriptions with the exception of the last test for the SHA-1 algorithm and the RIPEMD-160 algorithm.  The
	     last test for these is one million copies of the lower letter a.

     The default CRC used is based on the polynomial used for CRC error checking in the networking standard ISO/IEC 8802-3:1989.  The CRC checksum
     encoding is defined by the generating polynomial:

	   G(x) = x^32 + x^26 + x^23 + x^22 + x^16 + x^12 +
		x^11 + x^10 + x^8 + x^7 + x^5 + x^4 + x^2 + x + 1

     Mathematically, the CRC value corresponding to a given file is defined by the following procedure:

	   The	n  bits to be evaluated are considered to be the coefficients of a mod 2 polynomial M(x) of degree n-1.  These n bits are the bits
	   from the file, with the most significant bit being the most significant bit of the first octet of the file and the last bit	being  the
	   least  significant bit of the last octet, padded with zero bits (if necessary) to achieve an integral number of octets, followed by one
	   or more octets representing the length of the file as a binary value, least significant octet first.  The  smallest	number	of  octets
	   capable of representing this integer are used.

	   M(x)  is multiplied by x^32 (i.e., shifted left 32 bits) and divided by G(x) using mod 2 division, producing a remainder R(x) of degree
	   <= 31.

	   The coefficients of R(x) are considered to be a 32-bit sequence.

	   The bit sequence is complemented and the result is the CRC.

     The cksum and sum utilities exit 0 on success, and >0 if an error occurs.

SEE ALSO

     openssl(1), mtree(8)

     The default calculation is identical to that given in pseudo-code in the following ACM article.

     Dilip V. Sarwate, "Computation of Cyclic Redundancy Checks Via Table Lookup", Communications of the ACM, August 1988.

     R. Rivest, The MD2 Message-Digest Algorithm, RFC 1319.

     R. Rivest, The MD4 Message-Digest Algorithm, RFC 1186 and RFC 1320.

     R. Rivest, The MD5 Message-Digest Algorithm, RFC 1321.

     U.S. DOC/NIST, Secure Hash Standard, FIPS PUB 180-1.

STANDARDS

     The cksum utility is expected to conform to IEEE Std 1003.1-2004 (``POSIX.1'').

HISTORY

     The cksum utility appeared in 4.4BSD.  md5 was added in NetBSD 1.3.  The functionality for md2, md4, sha1, and rmd160 was added in
     NetBSD 1.6.  Support for the SHA-2 algorithms (SHA256, SHA384, and SHA512) was added in NetBSD 3.0.  The functionality to verify checksum
     stored in a file (-c) first appeared in NetBSD 4.0.

BSD
								   June 24, 2012							       BSD